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1. Susceptible host availability modulates climate effects on dengue dynamics

   https://doi.org/10.1101/2019.12.20.883363  

   Nova, Nicole ; Deyle, Ethan R. ; Shocket, Marta S. ; MacDonald, Andrew J. ; Childs Marissa L., Rypdal Martin ( May 2021 , Ecology letters)

   Experiments and models suggest that climate affects mosquito-borne disease transmission. However, disease transmission involves complex nonlinear interactions between climate and population dynamics, which makes detecting climate drivers at the population level challenging. By analysing incidence data, estimated susceptible population size, and climate data with methods based on nonlinear time series analysis (collectively referred to as empirical dynamic modelling), we identified drivers and their interactive effects on dengue dynamics in San Juan, Puerto Rico. Climatic forcing arose only when susceptible availability was high: temperature and rainfall had net positive and negative effects respectively. By capturing mechanistic, nonlinear and context-dependent effects of population susceptibility, temperature and rainfall on dengue transmission empirically, our model improves forecast skill over recent, state-of-the-art models for dengue incidence. Together, these results provide empirical evidence that the interdependence of host population susceptibility and climate drives dengue dynamics in a nonlinear and complex, yet predictable way. 

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2. Impact of prior and projected climate change on US Lyme disease incidence

   https://doi.org/10.1111/gcb.15435  

   Couper, Lisa I. ; MacDonald, Andrew J. ; Mordecai, Erin A. ( November 2020 , Global Change Biology)

   Lyme disease is the most common vector‐borne disease in temperate zones and a growing public health threat in the United States (US). The life cycles of the tick vectors and spirochete pathogen are highly sensitive to climate, but determining the impact of climate change on Lyme disease burden has been challenging due to the complex ecology of the disease and the presence of multiple, interacting drivers of transmission. Here we incorporated 18 years of annual, county‐level Lyme disease case data in a panel data statistical model to investigate prior effects of climate variation on disease incidence while controlling for other putative drivers. We then used these climate–disease relationships to project Lyme disease cases using CMIP5 global climate models and two potential climate scenarios (RCP4.5 and RCP8.5). We find that interannual variation in Lyme disease incidence is associated with climate variation in all US regions encompassing the range of the primary vector species. In all regions, the climate predictors explained less of the variation in Lyme disease incidence than unobserved county‐level heterogeneity, but the strongest climate–disease association detected was between warming annual temperatures and increasing incidence in the Northeast. Lyme disease projections indicate that cases in the Northeast will increase significantly by 2050 (23,619 ± 21,607 additional cases), but only under RCP8.5, and with large uncertainty around this projected increase. Significant case changes are not projected for any other region under either climate scenario. The results demonstrate a regionally variable and nuanced relationship between climate change and Lyme disease, indicating possible nonlinear responses of vector ticks and transmission dynamics to projected climate change. Moreover, our results highlight the need for improved preparedness and public health interventions in endemic regions to minimize the impact of further climate change‐induced increases in Lyme disease burden.

    

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3. AeDES: a next-generation monitoring and forecasting system for environmental suitability of Aedes-borne disease transmission

   https://doi.org/10.1038/s41598-020-69625-4  

   Muñoz, Á. G. ; Chourio, X. ; Rivière-Cinnamond, Ana ; Diuk-Wasser, M. A. ; Kache, P. A. ; Mordecai, E. A. ; Harrington, L. ; Thomson, M. C. ( December 2020 , Scientific Reports)

   null (Ed.)

   Abstract Aedes -borne diseases, such as dengue and chikungunya, are responsible for more than 50 million infections worldwide every year, with an overall increase of 30-fold in the last 50 years, mainly due to city population growth, more frequent travels and ecological changes. In the United States of America, the vast majority of Aedes -borne infections are imported from endemic regions by travelers, who can become new sources of mosquito infection upon their return home if the exposed population is susceptible to the disease, and if suitable environmental conditions for the mosquitoes and the virus are present. Since the susceptibility of the human population can be determined via periodic monitoring campaigns, the environmental suitability for the presence of mosquitoes and viruses becomes one of the most important pieces of information for decision makers in the health sector. We present a next-generation monitoring and forecasting system for $$\underline{\textit{Ae}}{} \textit{des}$$ Ae ̲ des -borne d iseases’ e nvironmental s uitability ( Ae DES) of transmission in the conterminous United States and transboundary regions, using calibrated ento-epidemiological models, climate models and temperature observations. After analyzing the seasonal predictive skill of Ae DES, we briefly consider the recent Zika epidemic, and the compound effects of the current Central American dengue outbreak happening during the SARS-CoV-2 pandemic, to illustrate how a combination of tailored deterministic and probabilistic forecasts can inform key prevention and control strategies . 

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4. Scoping review of Culex mosquito life history trait heterogeneity in response to temperature

   https://doi.org/10.1186/s13071-023-05792-3  

   Moser, S. Kane ; Barnard, Martha ; Frantz, Rachel M. ; Spencer, Julie A. ; Rodarte, Katie A. ; Crooker, Isabel K. ; Bartlow, Andrew W. ; Romero-Severson, Ethan ; Manore, Carrie A. ( June 2023 , Parasites & Vectors)

   Mosquitoes in the genusCulexare primary vectors in the US for West Nile virus (WNV) and other arboviruses. Climatic drivers such as temperature have differential effects on species-specific changes in mosquito range, distribution, and abundance, posing challenges for population modeling, disease forecasting, and subsequent public health decisions. Understanding these differences in underlying biological dynamics is crucial in the face of climate change.

   We collected empirical data on thermal response for immature development rate, egg viability, oviposition, survival to adulthood, and adult lifespan forCulex pipiens, Cx. quinquefasciatus, Cx. tarsalis, andCx. restuansfrom existing literature according to the PRISMA scoping review guidelines.

   We observed linear relationships with temperature for development rate and lifespan, and nonlinear relationships for survival and egg viability, with underlying variation between species. Optimal ranges and critical minima and maxima also appeared varied. To illustrate how model output can change with experimental input data from individualCulexspecies, we applied a modified equation for temperature-dependent mosquito type reproduction number for endemic spread of WNV among mosquitoes and observed different effects.

   Current models often input theoretical parameters estimated from a single vector species; we show the need to implement the real-world heterogeneity in thermal response between species and present a useful data resource for researchers working toward that goal.

    

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5. Climate predicts geographic and temporal variation in mosquito-borne disease dynamics on two continents

   https://doi.org/10.1038/s41467-021-21496-7  

   Caldwell, Jamie M. ; LaBeaud, A. Desiree ; Lambin, Eric F. ; Stewart-Ibarra, Anna M. ; Ndenga, Bryson A. ; Mutuku, Francis M. ; Krystosik, Amy R. ; Ayala, Efraín Beltrán ; Anyamba, Assaf ; Borbor-Cordova, Mercy J. ; et al ( December 2021 , Nature Communications)

   null (Ed.)

   Abstract Climate drives population dynamics through multiple mechanisms, which can lead to seemingly context-dependent effects of climate on natural populations. For climate-sensitive diseases, such as dengue, chikungunya, and Zika, climate appears to have opposing effects in different contexts. Here we show that a model, parameterized with laboratory measured climate-driven mosquito physiology, captures three key epidemic characteristics across ecologically and culturally distinct settings in Ecuador and Kenya: the number, timing, and duration of outbreaks. The model generates a range of disease dynamics consistent with observed Aedes aegypti abundances and laboratory-confirmed arboviral incidence with variable accuracy (28–85% for vectors, 44–88% for incidence). The model predicted vector dynamics better in sites with a smaller proportion of young children in the population, lower mean temperature, and homes with piped water and made of cement. Models with limited calibration that robustly capture climate-virus relationships can help guide intervention efforts and climate change disease projections. 

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